EP0566696A1 - Controller for spark discharge imaging. - Google Patents
Controller for spark discharge imaging.Info
- Publication number
- EP0566696A1 EP0566696A1 EP92905826A EP92905826A EP0566696A1 EP 0566696 A1 EP0566696 A1 EP 0566696A1 EP 92905826 A EP92905826 A EP 92905826A EP 92905826 A EP92905826 A EP 92905826A EP 0566696 A1 EP0566696 A1 EP 0566696A1
- Authority
- EP
- European Patent Office
- Prior art keywords
- cylinder
- image
- imaging
- printing
- signal
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Granted
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Classifications
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B41—PRINTING; LINING MACHINES; TYPEWRITERS; STAMPS
- B41C—PROCESSES FOR THE MANUFACTURE OR REPRODUCTION OF PRINTING SURFACES
- B41C1/00—Forme preparation
- B41C1/10—Forme preparation for lithographic printing; Master sheets for transferring a lithographic image to the forme
- B41C1/1008—Forme preparation for lithographic printing; Master sheets for transferring a lithographic image to the forme by removal or destruction of lithographic material on the lithographic support, e.g. by laser or spark ablation; by the use of materials rendered soluble or insoluble by heat exposure, e.g. by heat produced from a light to heat transforming system; by on-the-press exposure or on-the-press development, e.g. by the fountain of photolithographic materials
- B41C1/1033—Forme preparation for lithographic printing; Master sheets for transferring a lithographic image to the forme by removal or destruction of lithographic material on the lithographic support, e.g. by laser or spark ablation; by the use of materials rendered soluble or insoluble by heat exposure, e.g. by heat produced from a light to heat transforming system; by on-the-press exposure or on-the-press development, e.g. by the fountain of photolithographic materials by laser or spark ablation
-
- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04N—PICTORIAL COMMUNICATION, e.g. TELEVISION
- H04N1/00—Scanning, transmission or reproduction of documents or the like, e.g. facsimile transmission; Details thereof
- H04N1/04—Scanning arrangements, i.e. arrangements for the displacement of active reading or reproducing elements relative to the original or reproducing medium, or vice versa
- H04N1/047—Detection, control or error compensation of scanning velocity or position
- H04N1/053—Detection, control or error compensation of scanning velocity or position in main scanning direction, e.g. synchronisation of line start or picture elements in a line
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04N—PICTORIAL COMMUNICATION, e.g. TELEVISION
- H04N1/00—Scanning, transmission or reproduction of documents or the like, e.g. facsimile transmission; Details thereof
- H04N1/46—Colour picture communication systems
- H04N1/50—Picture reproducers
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04N—PICTORIAL COMMUNICATION, e.g. TELEVISION
- H04N1/00—Scanning, transmission or reproduction of documents or the like, e.g. facsimile transmission; Details thereof
- H04N1/04—Scanning arrangements, i.e. arrangements for the displacement of active reading or reproducing elements relative to the original or reproducing medium, or vice versa
- H04N1/06—Scanning arrangements, i.e. arrangements for the displacement of active reading or reproducing elements relative to the original or reproducing medium, or vice versa using cylindrical picture-bearing surfaces, i.e. scanning a main-scanning line substantially perpendicular to the axis and lying in a curved cylindrical surface
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04N—PICTORIAL COMMUNICATION, e.g. TELEVISION
- H04N2201/00—Indexing scheme relating to scanning, transmission or reproduction of documents or the like, and to details thereof
- H04N2201/024—Indexing scheme relating to scanning, transmission or reproduction of documents or the like, and to details thereof deleted
- H04N2201/02406—Arrangements for positioning elements within a head
- H04N2201/02439—Positioning method
- H04N2201/02443—Positioning method using adhesive
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04N—PICTORIAL COMMUNICATION, e.g. TELEVISION
- H04N2201/00—Indexing scheme relating to scanning, transmission or reproduction of documents or the like, and to details thereof
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- H04N2201/047—Detection, control or error compensation of scanning velocity or position
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- H04N2201/0471—Detection of scanning velocity or position using dedicated detectors
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- H04N2201/04—Scanning arrangements
- H04N2201/047—Detection, control or error compensation of scanning velocity or position
- H04N2201/04701—Detection of scanning velocity or position
- H04N2201/04715—Detection of scanning velocity or position by detecting marks or the like, e.g. slits
- H04N2201/04717—Detection of scanning velocity or position by detecting marks or the like, e.g. slits on the scanned sheet, e.g. a reference sheet
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- H04N2201/047—Detection, control or error compensation of scanning velocity or position
- H04N2201/04701—Detection of scanning velocity or position
- H04N2201/04715—Detection of scanning velocity or position by detecting marks or the like, e.g. slits
- H04N2201/04724—Detection of scanning velocity or position by detecting marks or the like, e.g. slits on a separate encoder wheel
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- H04N2201/047—Detection, control or error compensation of scanning velocity or position
- H04N2201/04701—Detection of scanning velocity or position
- H04N2201/04734—Detecting at frequent intervals, e.g. once per line for sub-scan control
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- H04N2201/04753—Control or error compensation of scanning position or velocity
- H04N2201/04758—Control or error compensation of scanning position or velocity by controlling the position of the scanned image area
- H04N2201/04767—Control or error compensation of scanning position or velocity by controlling the position of the scanned image area by controlling the timing of the signals, e.g. by controlling the frequency o phase of the pixel clock
- H04N2201/04768—Controlling the frequency of the signals
- H04N2201/04772—Controlling the frequency of the signals using a phase-locked loop
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- H04N2201/00—Indexing scheme relating to scanning, transmission or reproduction of documents or the like, and to details thereof
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- H04N2201/047—Detection, control or error compensation of scanning velocity or position
- H04N2201/04753—Control or error compensation of scanning position or velocity
- H04N2201/04793—Control or error compensation of scanning position or velocity using stored control or compensation data, e.g. previously measured data
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- H—ELECTRICITY
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- H04N—PICTORIAL COMMUNICATION, e.g. TELEVISION
- H04N2201/00—Indexing scheme relating to scanning, transmission or reproduction of documents or the like, and to details thereof
- H04N2201/04—Scanning arrangements
- H04N2201/047—Detection, control or error compensation of scanning velocity or position
- H04N2201/04753—Control or error compensation of scanning position or velocity
- H04N2201/04794—Varying the control or compensation during the scan, e.g. using continuous feedback or from line to line
- H04N2201/04798—Varying the main-scan control during the main-scan, e.g. facet tracking
Definitions
- the invention relates generally to the field of imaging devices and, more specifically, to control circuitry for digitally operated imaging devices.
- Imaging printing plates include the use of electromagnetic- radiation pulses, produced by one or more laser or non-laser sources, to create chemical changes at selected points of sensitized plate blanks, which are used (immediately or after exposure to conventional development processes) for planographic printing; ink-jet equipment that is used to selectively deposit ink-repellent or ink-accepting spots on plate blanks, also to produce planographic printing plates; and spark-discharge equipment, in which an electrode in contact with or spaced close to a plate blank produces electrical sparks to alter the characteristics of certain areas on a printing surface, thereby producing "dots" which collectively form a desired image.
- electromagnetic- radiation pulses produced by one or more laser or non-laser sources
- ink-jet equipment that is used to selectively deposit ink-repellent or ink-accepting spots on plate blanks, also to produce planographic printing plates
- spark-discharge equipment in which an electrode in contact with or spaced close to a plate blank produces electrical sparks to alter the characteristics of certain areas
- imaging device includes radiation sources, ink-jet sources, electrodes and other known means of producing image spots on blank printing plates, and the term “discharge” means the image- forming emissions produced by these devices. Multiple imaging devices may be used to produce several lines of image spots simultaneously, with a corresponding increase in imaging speed.
- the operation of the imaging devices must be precisely controlled so that the discharges oc ⁇ iir at the appropriate times tc reach the intended dot locations on the printing surface. If the operation of the imaging devices is not properly controlled, various undesirable characteristics may appear in the image. For example, in imaging systems which images printing plates mounted on a rotatable cylinder, a condition which is referred to herein as "slanted swath" may be observed.
- the slanted swath condition is characterized by lines in the image which run in the axial direction as opposed to the circumferential direction, and which appear "sawtoothed" or jagged instead of straight.
- the slanted swath condition may occur as a result of one or a combination of factors.
- a mechanism is required to monitor the rotation of the cylinder and provide angular position information for synchronizing the operation of the imaging devices. In order to accurately resolve the correct discharge locations, it is essential to generate precise position information.
- Such information may be provided by an angular-position encoder which "divides" the circumference of the cylinder into a predetermined number of increments and generates an appropriate output signal (e.g., a series of pulses, each of which represents a unit of distance around the circumference of the cylinder) .
- the circumferential distances between such devices must be precisely fixed to represent an integral number of units of circumferential distance. Otherwise, a "dimensional error" between the angular position information and the devices will exist, which will result in premature or delayed firing of the devices with respect to the rotating cylinder, which will in turn result in the slanted swath condition. Typically, normal manufacturing tolerances produce variations in the circumferential distances between devices which represent a significant dimensional error.
- Manufacturing tolerances also produce variations in the dimensions (i.e., circumferences) of the printing plate cylinders.
- the four circumferences will not be the same.
- adjustments must be made to the operation of the imaging devices in order to produce four printing plates whose images are the same size in the circumferential direction.
- the most expedient way to make such adjustments is to alter the scaling or number of pulses produced by the angular position encoder.
- any change in the encoder's scaling will produce a dimensional error between the encoder and the imaging devices, which will again result in the slanted swath condition.
- Another printing artifact that may occur in digitally imaged printing plates is a series of parallel lines that traverses the printed document along the direction in which the plate was imaged. These lines appear most prominently when the plate-imaging equipment includes multiple-device writing heads, and can arise from any number of causes (such as failure of individual devices to image at the same intensity as other devices, incorrect orientation of the writing head, or improper alignment of individual imaging devices within the head) .
- a writing head consisting of a diagonal array of non-contact spark-discharge electrodes, we have found that the first electrode to make contact with the plate surface during each pass tends to produce image spots of diminished intensity; thus, streaks of uneven intensity will be produced even with a perfectly assembled writing head.
- the present invention provides an apparatus and method for controlling the discharges used to image printing plates.
- the invention is used in an imaging system which includes a press computer, a rotatable cylinder on which a printing plate is mounted, and a writing head which includes multiple imaging devicesfor producing image spots on the printing surface of the printing plate.
- the cylinder may be mounted on a platemaking apparatus, or can instead represent the plate drum of the press itself.
- the time intervals between discharges may be varied to effectively enlarge or shrink the size of the image in the circumferential direction, as well as to prevent the slanted swath condition.
- the present invention permits independent control of the timing of the discharges from each imaging device in a multi-device writing head.
- the present invention further provides a novel apparatus for sensing the angular position of the rotating cylinder.
- the apparatus operates on a relatively low-resolution angular position signal to produce a position signal of sufficient resolution to perform high density imaging while preventing the slanted swath condition.
- Figure 1 is a block diagram of an imaging and printing press system which incorporates the present invention
- Figure 2A is a perspective view of a spark discharge writing head
- Figure 2B is a front elevation of the writing head shown in Figure 2;
- Figure 3 is a block diagram of the image length and swath control unit shown in Figure 1;
- Figure 4 is a detailed diagram of the skew memory shown in Figure 3;
- FIG. 5 is a detailed diagram of the control logic unit- shown in Figure 3;
- Figure 6 is a flowchart diagram showing the operational steps performed by the image length and swath control unit shown in Figure 3;
- Figure 7A is a diagram showing correction data stored in the skew memory
- Figure 7B is a diagram shown modified correction data stored in the skew memory
- Figure 8 is a timing diagram depicting the relationships between various signals generated by the control unit shown in Figure 3;
- Figure 9A is a schematic circuit diagram of the driver shown in Figure 1;
- Figure 9B depicts three voltage waveforms which are related to the circuitry of Figure 9A;
- Figure 10 is a schematic circuit diagram of the sensor logic shown in Figure 3;
- Figure 11A is a schematic representation of a periodic artifact and the source thereof.
- Figure 11B is a schematic representation of our approach toward minimizing the visual impact of the artifact shown in Figure 11A.
- FIG. 1 depicts, in block diagram form, an imaging station 2, which may represent an independent platemaking apparatus or an integral assembly within a printing press. In the latter case, the station 2 may be used both to image printing plates "on press," and to subsequently print the desired material. It should be understood that multiple stations 2 may be employed to meet the requirements of a particular application. For example, a four-color spark discharge imaging and printing system may employ a total of four stations like the one depicted in Figure 1.
- the station 2 is controlled a press computer 4.
- the computer 4 is interfaced to an image length and swath control unit 6.
- the unit 6 is also interfaced, via drivers 7, to a writing head 8.
- the head 8 communicates with a printing plate 12 which is mounted on rotatable cylinder 10; the head 8 traverses the plate 12 axially (that is, from one side to the other) .
- the cylinder 10 includes a cut-out portion or void 14 which allows access for securing or removing the printing plate 12.
- An angular encoder 16 is coupled to one end of the cylinder 10 and to the control unit 6.
- image information in digital form is supplied to the computer 4 by way of a magnetic tape, disk, optical scanner, or other means of data input or transfer.
- Such information typically includes a data representation of the image which is to be formed on the printing plate 12, as well as related control information.
- the computer 4 may be used to generate the information necessary to image the printing plate 12.
- an operator causes the computer 4 to begin sending the necessary image data and control information to the control unit 6.
- the operator may accomplish this, for example, by using a keyboard, "mouse” or other input device to control the press computer 4.
- the cylinder 10 begins to rotate, and continues to do so with a substantially constant angular velocity.
- the functions of the control unit 6 are explained in detail below. However, for purposes of understanding the overall operation of the station 2, it is sufficient to say that the control unit 6 regulates the timing with which imaging data is supplied to the drivers 7 and, ultimately, the writing head 8.
- one or more imaging devices disposed in the head 8 will either discharge or not discharge, depending upon the binary state of the data.
- an imaging device discharges, it forms an image "spot" on the printing surface of the plate 12 (e.g., by ablation or surface transformation following spark discharge, exposure of a sensitized plate surface to radiation, deposition of a coating, etc.).
- An image spot is actually an area of the printing surface whose characteristics are altered by the discharge.
- the void 14 passes adjacent to the writing head 8, at which time the imaging devices are idle and no imaging occurs. At that time, the head 8 may be advanced in the axial direction in preparation for further imaging during the next revolution of the cylinder 10. As these steps are repeated, the writing head 8 eventually traverses (scans) the full length of the printing plate 12 in the axial direction (as shown in phantom) and a complete image is formed on the printing surface of the plate 12.
- FIG 2A is a perspective view of a preferred embodiment of the writing head 8, which is constructed for non- contact spark-discharge imaging.
- the head 8 includes an open- ended guard 18 which is curved so that it may reside in close proximity to the curved printing surface of the printing plate 12. Disposed within the guard 18 are sixteen individual styli electrodes 20.
- the head 8 also includes a U-shaped support 22 which holds the guard 18 and the electrodes 20.
- the support 22 is attached to a printed circuit board (PCB) 24.
- Sixteen terminals 26 are attached to the rear edge of PCB 24 and each of the electrodes 20 is electrically connected by a lead 28 to one of the terminals 26.
- the terminals 26 provide suitable electrical connections for connecting the head 8 to other components of the station 2.
- the electrodes 20 are arranged along a "diagonal" within the guard 18. (The slope of the "diagonal" in Figure 2B has been exaggerated for purposes of more clearly illustrating the placement of the electrodes) .
- the electrodes 20 are spaced sufficiently far apart to avoid electrical interference and/or grounding between adjacent electrodes. Because spacing in the axial direction is dictated by the desired resolution level (the spacing being equal to the reciprocal of the dot resolution) , the electrodes are separated in the circumferential direction by that distance required to produce the necessary absolute int ⁇ r-electrod ⁇ distance. Using a 16-electrode writing head, our preferred spacing is 0.001 inch (1 mil) in the axial direction, and 0.050 inch (50 mils) in the circumferential direction.
- the electrodes 20 are to be used to form image spots which are located on 1 mil centers in both the axial and circumferential directions. Because the electrodes 20 are spaced 50 mils apart in the circumferential direction, the firing of the electrodes 20 must be carefully controlled in order to discharge sparks at the appropriate times to form image spots in the correct locations on the printing surface. In order to achieve spark discharges at the appropriate times, the angular position information produced by the angular encoder 16 must be properly "synchronized" with the physical positions of the electrodes 20 in relation the printing surface. However, regardless of how one attempts to arrange the electrodes 20 and calibrate the encoder 16, it is neither economical nor practical to achieve a perfect dimensional "match" between those components. Accordingly, the present invention provides a method and apparatus for correcting such errors and controlling the size of the image in the circumferential direction.
- control unit 6 includes a skew memory 30 which receives as an input data from the press computer 4.
- Each of a plurality of swath memories 32 also receives data from the computer 4 as an input.
- the skew memory 30 provides data as an output to a control logic unit 36, and also receives control information from logic unit 36.
- Sensor logic unit 34 receives as an input angular position data from the angular encoder 16, and provides as an output enhanced-resolution position data to the unit 36.
- Each of a plurality of output memories 38 receives as an input data from an associated one of the swath memories 32.
- each output memory 38 receives as an input control information from the unit 36.
- Each of the output memories 38 provides as an output imaging dara, which is transmitted to an associated one of the drivers 7.
- unit 36 provides control information to the drivers 7, a void position status signal to the computer 4, and initialization information to the sensor logic unit 34.
- Figure 4 shows a preferred embodiment of the skew memory 30.
- the memory 30 includes an area of random access memory (RAM) 31 and an address generator (counter) 33.
- RAM 31 provides an array capable of storing N x 16 bits of data.
- RAM 31 is connected to receive sixteen data bits in parallel from the press computer 4, which bits are referred to herein as a "word" of "correction data.” RAM 31 is also connected to receive from address generator 33 sixteen address bits in parallel, as well as an OUTPUT ENABLE signal and a WRITE signal from the control logic unit 36. The address generator 33 is connected to receive an INCREMENT signal and a RESET signal from the unit 36. The functions of the various signals applied to the skew memory 30 are explained in detail below.
- the RESET signal operates to set the address generator to a predetermined starting address, which is simply the address that is designated to contain correction data corresponding to the first possible discharge location (in a circumferential sense) in a given swath of the imaging area.
- the term "swath" is used herein to refer to the maximum image area which the writing head 8 can cover during one revolution of the cylinder.
- the INCREMENT signal causes the address generator 33 to advance the address applied to RAM 31 by one.
- the WRITE signal permits data received from the press computer 4 to be stored at the address supplied by the address generator 33.
- the OUTPUT ENABLE signal permits the transmission of a correction data word, stored at the address supplied by the address generator 33, to the control logic unit 36.
- the skew memory 30 requires a minimum capacity of 160K x 16 bits to simultaneously store all of the correction data for one revolution of the plate 12.
- the skew memory 30 is implemented using a RAM organized as an array of 262K x 16 bits.
- the additional capacity (approximately 102K) over and above what is strictly needed for the skew memory 30 allows the RAM to be used for other, unrelated purposes when it is not needed to serve as the skew memory.
- the actual size or configuration of the skew memory 30 may be varied depending upon the desired correction resolution, the number of imaging devices, and other factors such as whether the data stored in the skew memory 30 is compressed or encoded, etc.
- the number of swath memories 32 and associated output memories 38 required depends upon the number of imaging devices in the writing head 8; in the embodiment shown, there is one swath memory 32 and one output memory 38 for each imaging device in the writing head.
- a total of sixteen swath memories 32 and sixteen output memories 38 are required.
- Each swath memory 32 is preferably implemented using a RAM and an associated address generator, similar to the arrangement shown in Figure 4. However, each swath memory 32 is connected to receive imaging data from the press computer 4, as opposed to correction data. The imaging data is a representation of the image which is to be formed on the printing surface of the printing plate 12. In addition, each swath memory 32 and its associated address generator are connected to receive OUTPUT ENABLE, WRITE, INCREMENT and RESET signals from the control logic unit 36, which signals are functionally similar to, but separate from, the signals applied to the skew memory 30.
- swath memories 32 are not necessary to use sixteen separate memories to implement the swath memories 32.
- a single RAM organized as an array of 16K x 16 bits is used to physically implement sixteen swath memories 32.
- the size or configuration of the swath memories 32 may be varied depending upon the requirements of a particular application, such as the required imaging speed, the circumferential length of the image, whether the imaging data is encoded or compressed, the desired imaging resolution and the like.
- each of the output memories 38 preferably comprises a conventional first-in-first- out (FIFO) memory having six one-bit storage locations.
- FIFO first-in-first- out
- FIG. 5 depicts a preferred embodiment for the control logic unit 36.
- the unit 36 includes four counters 35 which are interconnected with an algorithmic state machine (ASM) 37.
- ASM algorithmic state machine
- Counter 35a is connected to receive position pulses from the sensor logic unit 34.
- Each of the position pulses from unit 34 represents a predetermined unit of distance in the circumferential direction around the printing surface of the printing plate 12.
- each position pulse produced b the unit 34 represents 0.0001 inch (0.1 mil) of distance in the circumferential direction.
- ASM 37 may be implemented, for example, by storing data in a programmable read-only memory (PROM) which represents a control algorithm. That is, for each possible combination of address signals that is applied to the PROM, a predetermined combination of output (data) signals are produced by the PROM.
- PROM programmable read-only memory
- control logic unit 36 may be implemented in any of a variety of ways depending upon the requirements of a particular application. For example, a microprocessor or microcontroller, along with an area of non ⁇ volatile memory for storing instructions, may be programmed in a conventional manner to perform the functions of ASM 37.
- ASM 37 is connected to receive both position pulses and home pulses from the sensor logic unit 34.
- a home pulse is preferably a single pulse which occurs once per revolution of the cylinder 10, which serves as a marker to indicate when a revolution is completed.
- Counters 35 produce output signals which indicate when the following conditions occurs: (1) the beginning of the imaging area on the printing surface of the plate 12 is approaching the writing head 8; (2) the end of the imaging area is approaching; (3) the beginning of the void 14 is approaching; or (4) the end of the void 14 is approaching.
- imaging area means the portion of the total printing surface area in which an image may be formed, and excludes the “margins” or borders which are left blank.
- the counters 35 are initialized to predetermined starting values.
- the starting values for the counters are initially calculated by knowing the circumferential distance represented by each position pulse, the circumference of the plate 12 and the angular extents of the void 14 and imaging area.
- the starting values are preferably chosen such that each counter 35 will reach its maximum value contemporaneously with the occurrence of the condition of interest (e.g., the beginning of the void).
- Initialization of the counters 35 occurs when a RESET signal is applied to the counters by the ASM 37, at which time each counter is set to a value represented by the signals present at the inputs of the counter.
- the control information supplied by ASM 37 to the output memories 38 consists of three signals: STEP DATA IN, STEP DATA OUT and RESET.
- the STEP DATA IN signal operates tc serially load (from the output of the associated swath memory 32) a single data bit into the output memory 38, while the STEP DATA OUT signal is used to serially transmit a single data bit from the memory 38 to an associated driver 7.
- the RESET signal clears the output memories 38.
- the control information supplied by ASM 37 to the drivers 7 consists of pulses which are used to initiate firing of the imaging devices, which pulses are described below in connection with Figure 9A.
- control logic unit 36 wil now be described, with reference to Figures 5, 6 and 8A. Operation starts at step 42 upon power up of the station 2.
- the unit 6 initializes at step 44, during which the ASM 37 issues a RESET signal to the skew memory 30, which operates to set the address generator 33 to the predetermined starting address previously described.
- the ASM 37 issues a RESET signal to the swath memories 32, which sets the address generator(s) associated with such memories to predetermined starting addresses.
- the starting address for a swath memory 32 is simply the address which is designated to contain imaging data corresponding to the first image spot (whether blank or not) of a given swath of the image.
- a RESET signal is also issued to the output memories 38, which clears them.
- the unit 36 also provides initialization information to the unit 34 (which is described below in connection with Figure 10) and sets the four counters within the unit 36 which are used to determine the boundaries of the imaging area and the void 14.
- the skew memory 30 is loaded by the computer 4, in cooperation with the unit 36, with predetermined correction data which will be used to prevent the slanted swath condition and to control the size of the image in the circumferential direction.
- the loading of the skew memory 30 entails the assertion of a WRITE signal from the unit 36, followed by transmission of a word of correction data from the computer 4, which word is stored in the skew memory 30 at the address specified by the address generator 33.
- An INCREMENT signal is then issued from the unit 36, which increments the address generator 33. This process continues until all of the correction data is stored in the skew memory 30.
- the skew memory 30 is loaded only once during initialization and the correction data stored therein is used for all subsequent imaging.
- a method for deriving the correction data used in the skew memory 30 will now be described.
- a four-color imaging and printing system having four imaging stations 2 is used.
- an imaging resolution of 1.0 mil and a correction resolution of 0.1 mil are desired.
- each of the four imaging stations 2 is used to image and print a "standard" test pattern.
- the skew memory 30 is loaded with "nominal” or neutral correction data, which essentially allows the test pattern image data to pass through to the drivers 7 without adjustment in the circumferential direction.
- "nominal" correction data for the skew memory 30 may consist of storing all binary ones at the first address of the skew memory 30 (corresponding the first possible discharge location on a given revolution of the cylinder 10) , followed by all binary zeros in the next nine successive addresses, and repeating this pattern through the entire skew memory 30.
- the effect of such "nominal" correction data is simply to allow one bit of imaging data to be advanced from the output memories 38 to the drivers 7 every 1.0 mil of distance in the circumferential direction, which represents the distance between nominal image-spot locations.
- Desired amounts of enlargement or shrinkage in the circumferential direction, within the limits of the imaging area of the printing plate 12, may be spread uniformly, or otherwise, across the length of the image by selectively altering the correction data values stored in the skew memory 30.
- the swath memories 32 are loaded with imaging data for the first swath to be imaged on the printing surface of the plate 12.
- the swath memories 32 are loaded in a manner similar to that described above with respect to the skew memory 30, except that imaging data is loaded instead of correction data.
- imaging data is loaded instead of correction data.
- a total of 16K x 16 image data bits are loaded by the press computer 4 into the swath memories 32 during step 46.
- the unit 36 issues an OUTPUT ENABLE signal to the swath memories 32 and a STEP DATA IN signal to the output memories 38, which causes the first data bits appearing at the outputs of the memories 32 (collectively, a sixteen-bit word of image data) to be advanced into the first storage locations of memories 38.
- the unit 36 then issues an INCREMENT signal to all of the swath memories 32, which causes their respective address generators to increase by one.
- An OUTPUT ENABLE signal is again issued to the swath memories 32 and the steps are repeated until a total of three bits of image data are stored in each of the output memories 38, and the address generators for the swath memories 32 are set to the addresses for the fourth bits of image data.
- the station 2 is ready to actually start imaging at step 50.
- the cylinder 10 is rotating at a generally constant angular velocity, and angular position data generated by the sensor logic unit 34 is transmitted to the unit 36.
- the unit 36 also receives a word of correction data from the skew memory 30 (the word stored at the address corresponding to the predetermined starting address) .
- the unit 36 may associate or synchronize a known angular position of the cylinder 10 with this first word of correction data.
- the first word of correction data is synchronized with the first possible discharge location of a given swath, thereby synchronizing subsequent correction data words sequentially with successive possible discharge locations.
- Each correction data word stored in the skew memory 30 indicates whether the image data for a particular imaging device should be advanced to the drivers 7.
- the eighth bit (corresponding to the eighth imaging device of a sixteen-device writing head) of the sixteen-bit correction data words is used to indicate when the next word of image data stored in the swath memories 32 should be advanced to the output memories 38. If the eighth bit of the output word from the skew memory 30 is a binary one, the imaging control process continues to step 54.
- the eighth bit of the correction data words has been chosen for purposes of illustrating the "trigger" for advancing data from the swath memories 32 to the output memories 38, the ninth bit would function in a comparable manner.
- the significance of the eighth bit is that it corresponds to the eighth imaging device, which is physically close to the exact middle of a sixteen-device swath. Therefore, the eighth bit (imaging device) is a logical choice as a "reference" whose actual discharge location is neither advanced nor retarded from its nominal location. Viewed another way, only the discharges corresponding to bits other than the eighth bit are subject to being moved forward or backward, thus producing a skew about the eighth bit.
- step 54 the unit 36 issues a STEP DATA OUT signal to those output memories 38 whose corresponding bits in the output word from the skew memory 38 are binary ones. Due to the conditional test of step 52, it is known that at least the eighth bit of the output word from the skew memory 38 is a binary one. Therefore, at least that output memory 38 which corresponds to the eighth imaging device will be issued a STEP DATA OUT signal at this time. Depending upon the binary values for bits 1-7 and 9-16 of the output word from the skew memory 30, the output memories 38 which correspond to those bits may be issued their STEP DATA OUT signals slightly before or slightly after that which is issued with respect to the eighth imaging device. In this fashion, each output memory 38, and the firing of its associated imaging device, may be independently controlled by the unit 36.
- the unit 36 sends a control signal to the drivers 7 which actually initiates the discharge of the individual imaging devices.
- the unit 36 then asserts an INCREMENT signal to the swath memories 32, which causes the next word of image data to appear at the outputs of the memories 32.
- This is followed by a STEP DATA IN signal to the output memories 38 which advances the data word into the output memories 38.
- the skew memory 30 address is then advanced at step 56 by the assertion of the INCREMENT signal by the unit 36.
- step 52 If, during step 52, the eighth bit of the output word from the skew memory 30 is not a binary one (meaning that no image data is to be advanced to the output memories 38 at that particular time) , the imaging control process bypasses step 54, and moves to step 56 in which the unit 36 issues an INCREMENT signal to increment the address of the skew memory 30. In response, the next sequential word is output by the skew memory 30 and is examined by the unit 36. If any of the bits of the output word is a binary one, the unit 36 will issue a STEP DATA OUT signal to the corresponding output memory 38 and also send the appropriate control signal to the drivers 7.
- the skew memory 30 contains ten words of correction data corresponding to each 1.0 mil of circumferential distance. That explains why the address of the skew memory 30 is advanced multiple times between advances of the swath memories 1 addresses. Therefore, by specifying which bits of the words stored in the skew memory 30 contain a binary one, the actual discharge locations may be moved forward or backward (circumferentially) by a desired number of 0.1 mil increments to prevent the slanted swath condition and to adjust the image size.
- the unit 36 checks the cumulative number of position pulses received from the unit 34 since the beginning of the current revolution of the cylinder 10. Based on the pulse count, the unit 36 determines whether the cylinder 10 has rotated sufficiently far so that the writing head- 8 has reached the end of the imaging area for the current swath (e.g., is the END OF IMAGING AREA signal present) . If the end of the imaging area has not been reached, the imaging control process returns to step 52 and, as before, checks the eighth bit of the output word from the skew memory 30 to determine whether to advance additional image data to the drivers 7.
- step 58 If, during step 58, it is determined that the current swath is complete, meaning that the void 14 is approaching the writing head 8, the process continues to step 60 during which the unit 36 asserts the VOID POSITION STATUS signal. While that signal is asserted, the press computer 4 is permitted to transmit new image data into the swath memories 32. As the void 14 completes its pass by the head 8 (the END OF VOID signal occurs) , the unit 36 stops asserting the VOID POSITION STATUS signal and the computer 4 is prevented from transmitting further imaging data to the swath memories 32.
- step 62 the unit 36 determines whether the image is complete. That determination is made by checking the swath memories 32 to determine whether new image data was actually loaded by the press computer 4. If not, meaning that no more image data remains, the image is complete and the process ends at step 64. If so, meaning that there is at least one more swath of imaging to perform, the process returns to step 48 and proceeds as before. Steps 60 and 62 are preferably executed during the period of each revolution when the void 14 is adjacent to the writing head 8, thus allowing the station 2 to prepare to image the next swath during the time when the writing head 8 is normally idle.
- Figure 9A is a circuit diagram of a suitable one of the drivers 7 shown in Figure 1, configured to operate a spark- discharge electrode.
- a monostable multivibrator 66 is connected to receive, as inputs, pulses from the control logic unit 36.
- An output of the multivibrator 66 is connected to one input of an AND gate 68.
- a second input of the AND gate 68 is connected to receive imaging data from one of the output memories 38.
- An output of the AND gate 68 is connected to the input of a high speed, high current MOSFET driver 70, whose output is connected to the gate of a MOSFET 72.
- the source of the MOSFET 72 is connected to ground potential.
- a primary winding of a transformer 76 is connected between the drain of the MOSFET 72 and a voltage supply(500 VDC) .
- a diode 74 is connected in parallel with the primary winding, with the anode of the diode connected to the drain of the MOSFET 72.
- One end of a secondary winding of the transformer 76 is connected to ground potential.
- a resistance 80 is connected between the second end of the secondary winding and the anode of a diode 78, whose cathode is connected to ground.
- a resistance 82 is connected in series between resistance 80 and an electrode 20.
- driver circuit 7 may be understood best with reference to both Figures 9A and 9B.
- imaging data is applied from the output memory to the AND gate 68 and a pulse is output from the multivibrator 66 in response to a control signal from unit 36
- AND gate 68 generates a fire pulse, which is amplified by driver 70 and applied to the gate of MOSFET 72.
- driver 70 and applied to the gate of MOSFET 72.
- the duration of the fire pulse is on the order of 100 nanoseconds and its magnitude is approximately 5V.
- the drain voltage of the MOSFET 72 decreases rapidly from the supply voltage to zero.
- the driver circuit 7 In order to achieve satisfactory imaging speeds, the driver circuit 7 must and does achieve a rise time on the order of 10 9 volts/second in producing the electrode voltage. In addition, protection should be provided such that excessive currents and incorrect electrode voltage polarity are avoided.
- Resistance 82 serves to limit the current delivered to the electrode 20, while resistance 80 in combination with diode 78 provide a clamp which prevents the polarity of the electrode voltage from becoming positive with respect to ground.
- FIG 10 is a circuit diagram of the sensor logic unit 34 shown in Figure 3.
- the major components of the unit 34 are a phase locked loop (PLL) 84, a first programmable divider 86 and a second programmable divider 88.
- PLL 84 consists of a phase comparator 90 having a first input which is connected to the angular encoder 16 ( Figure 1) .
- An output of the comparato 90 is connected to the input of a low pass filter 92.
- the output of the filter 92 is connected to the input of a voltage controlled oscillator (VCO) 94.
- VCO voltage controlled oscillator
- the output of the VCO 94 is fed back, via the divider 96, to a second input to the comparator 90.
- the output of the VCO 94 is connected to the input of the divider 86.
- the dividers 86 and 96 are programmed by the unit 36 as part of the initialization step 44 ( Figure 6) . That is, each divider is loaded with a integer value (P or N) which function as its divisor.
- P or N integer value which function as its divisor.
- the sensor logic unit 34 operates to enhance a relatively low resolution angular position signal produced by the angular encoder to yield a position signal having a substantially enhanced resolution.
- a relatively inexpensive, off-the-shelf angular encoder may be employed, yet sufficient angular position resolution is obtained.
- FIG. 11A shows a series of complementary image fragments 120a, 120b, 120c and 12Od printed by black, magenta, cyan and yellow printing plates, respectively.
- Each plate is imaged by an independent image or writing head depicted generically at 122 and shown schematically at 122a, 122b, 122c and 122d.
- Each head itself includes 16 imaging devices that traverse the plate in the indicated direction of relative motion.
- the head is shifted, or stepped, to the left by an amount sufficient to place the first imaging device of the array adjacent the next scan line.
- the four vertical lines in each fragment represent streaked printing artifacts caused by any of the flaws described above. Because the streaks recur at intervals equal to the width of the writing heads, one can infer that a single flaw is associated with each head. Specifically, the illustrated positions of the streaks suggest that, in each case, the lead imaging device is responsible.
- the four image fragments 120a, 120b, 120c and 12Od are sequentially impressed onto the same physical location of the recording medium; in other words, they are printed in register.
- the final composite image, representing these fragments overlaid one on another, is indicated by reference numeral 124. Because they are printed in register, the four vertical artifacts reinforce one another, as shown by the heavy vertical lines.
- FIG. 11B Our solution to this problem is shown in Figure 11B. Essentially, it involves staggering the initial imaging positions of the writing heads, so that artifacts caused by similarly situated elements within the heads do not appear at the same positions on the plates, and also appear less visually prominent due the their proximity to one another.
- writing head 122a (corresponding to black) begins imaging at the same initial position as was the case in Figure 11A
- writing head 122b (corresponding to magenta) is positioned only partially over the imaging area such that during the initial imaging pass, only the last four (of sixteen) imaging devices actually cover and produce discharges on the image area.
- writing head 122b is advanced by the usual stepping amount, and all 16 imaging devices are active (as shown by the succeeding set of circles) ; however, since the first pass was staggered, the position of each successive magenta vertical artifact is advanced by one- fourth the width of the writing heads.
- only the last eight imaging devices of writing head 122c (corresponding to cyan) produce discharges during the first imaging pass, thereby advancing the position of each successive cyan artifact by one-half the width of the writing heads, and only the last twelve imaging devices of writing head 122d (corresponding to yellow) produce discharges during the first imaging pass, thereby advancing the position of each successive yellow artifact by three-fourths the width of the writing heads.
- the final composite image is indicated by reference numeral 126, and shows how the vertical artifacts are closely and evenly spaced from one another.
- the same effect can be obtained, for example, by selecting a different imaging device in each array as the first device, thereby reducing the number of imaging devices that write during the first pass, and producing truncated swaths of differing widths.
- each head is stepped by a correspondingly smaller amount, so that at the second pass, the heads are positioned to produce full swaths at identical plate locations.
- the imaging devices of each writing head are non-contact electrodes axially spaced 0.001 inch apart (as shown in Figure 2B) ; the total width of each head, then, is 0.016 inch.
- the artifacts shown in Figure 11A will occur each 0.016 inch, corresponding to a frequency of 62.5 artifacts per inch. This frequency is small enough to be perceived by the human eye.
- the artifacts occur each 0.004 inch, or at a frequency of 250 artifacts per inch; under ordinary lighting and viewing conditions, the human eye cannot resolve such closely spaced features.
- the distance between artifacts can be reduced to a length equal to the width of each writing head divided by the total number of heads. It should also be noted that this technique can be applied to imaging systems having any number of independent heads and aging devices within each head.
- the staggering technique described above can be used to minimize the visual impact of this phenomenon; alternatively, the drive circuitry can be modified to apply greater voltage and/or current to the lead electrode in order to compensate for the deficiency in ablation.
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- Exposure And Positioning Against Photoresist Photosensitive Materials (AREA)
- Investigating, Analyzing Materials By Fluorescence Or Luminescence (AREA)
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Abstract
Appareil et procédé de commande de dispositifs de décharge utilisées pour former une image sur une plaque d'impression planographique. Des informations d'imagerie sont stockées dans une première mémoire tandis que des données de correction de décharge sont stockées dans une seconde mémoire. Les données de correction sont utilisées afin de varier les intervalles entre des décharges d'imagerie de manière à compenser les erreurs entre la position détectée de la plaque d'impression par rapport à une tête d'impression et la position effective. Les artefacts d'impression sont visuellement réduits au minimum par échelonnement des dispositifs d'imagerie utilisés pour produire des plaques de séparation.Apparatus and method for controlling discharge devices used to form an image on a planographic printing plate. Imaging information is stored in a first memory while discharge correction data is stored in a second memory. The correction data is used to vary the intervals between image discharges so as to compensate for errors between the detected position of the printing plate relative to a print head and the actual position. Printing artifacts are visually minimized by staggering the imaging devices used to produce separation plates.
Description
Claims
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
DE9219213U DE9219213U1 (en) | 1991-01-09 | 1992-01-07 | Control device for spark discharge imaging |
Applications Claiming Priority (3)
Application Number | Priority Date | Filing Date | Title |
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US07639199 US5174205B1 (en) | 1991-01-09 | 1991-01-09 | Controller for spark discharge imaging |
US639199 | 1991-01-09 | ||
PCT/US1992/000216 WO1992012592A2 (en) | 1991-01-09 | 1992-01-07 | Controller for spark discharge imaging |
Publications (2)
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EP0566696A1 true EP0566696A1 (en) | 1993-10-27 |
EP0566696B1 EP0566696B1 (en) | 1997-05-28 |
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Application Number | Title | Priority Date | Filing Date |
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EP92905826A Revoked EP0566696B1 (en) | 1991-01-09 | 1992-01-07 | Controller for spark discharge imaging |
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US (1) | US5174205B1 (en) |
EP (1) | EP0566696B1 (en) |
JP (1) | JP3091491B2 (en) |
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CA (1) | CA2099561C (en) |
DE (1) | DE69220035T2 (en) |
WO (1) | WO1992012592A2 (en) |
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1991
- 1991-01-09 US US07639199 patent/US5174205B1/en not_active Expired - Lifetime
-
1992
- 1992-01-07 AT AT92905826T patent/ATE153820T1/en not_active IP Right Cessation
- 1992-01-07 DE DE69220035T patent/DE69220035T2/en not_active Revoked
- 1992-01-07 JP JP04506187A patent/JP3091491B2/en not_active Expired - Lifetime
- 1992-01-07 CA CA002099561A patent/CA2099561C/en not_active Expired - Fee Related
- 1992-01-07 EP EP92905826A patent/EP0566696B1/en not_active Revoked
- 1992-01-07 WO PCT/US1992/000216 patent/WO1992012592A2/en not_active Application Discontinuation
Non-Patent Citations (1)
Title |
---|
See references of WO9212592A2 * |
Also Published As
Publication number | Publication date |
---|---|
DE69220035D1 (en) | 1997-07-03 |
US5174205B1 (en) | 1999-10-05 |
ATE153820T1 (en) | 1997-06-15 |
CA2099561A1 (en) | 1992-07-10 |
US5174205A (en) | 1992-12-29 |
CA2099561C (en) | 1997-04-08 |
JPH06507125A (en) | 1994-08-11 |
WO1992012592A2 (en) | 1992-07-23 |
JP3091491B2 (en) | 2000-09-25 |
EP0566696B1 (en) | 1997-05-28 |
DE69220035T2 (en) | 1997-12-11 |
WO1992012592A3 (en) | 1992-11-12 |
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